Scale effects on the attachment pads and friction forces in syrphid flies (Diptera, Syrphidae).

To test the role of constructional and dimensional factors in the generation of friction force by systems of setose attachment pads, six species of syrphid fly (Platycheirus angustatus, Sphaerophoria scripta, Episyrphus balteatus, Eristalis tenax, Myathropa florea and Volucella pellucens) were studied using light and scanning electron microscopy. Flies were selected according to their various body mass and attachment pad dimensions. Such variables as pad area, setal density, the area of a single setal tip and body mass were individually measured. A centrifugal force tester, equipped with a fibre-optic sensor, was used to measure the friction forces of the pads on a smooth horizontal surface made of polyvinylchloride. Friction force, which is the resistance force of the insect mass against the sum of centrifugal and tangential forces, was greater in heavier insects such as Er. tenax, M. florea and V. pellucens. Although lighter species generated lower frictional forces, the acceleration required to detach an insect was greater in smaller species. The area of attachment pads, setal tip area and setal density differed significantly in the species studied, and the dependence of these variables on body mass was significant. The frictional properties of the material of the setal tips were not dependent on the dimensions of the fly species. Similar results were obtained for the frictional properties of the pulvillus as a whole. Thus, the properties of the secretion and the mechanical properties of the material of the setal tips are approximately constant among the species studied. It is concluded that differences in friction force must be related mainly to variations in the real contact area generated by the pad on the smooth surface. The real contact area can be estimated as the summed area of the broadened setal tips of the pad in contact with the surface. The real contact area depends on such morphological variables as setal density and the area of a single setal tip. Although individual variables vary among flies with different dimensions, they usually compensate such that smaller setal tip area is partially compensated for by higher setal density.

[1]  L. Roth,et al.  Tarsal structure and climbing ability of cockroaches , 1952 .

[2]  J. Shea,et al.  Sliding Friction-Physical Principles and Applications , 1998, IEEE Electrical Insulation Magazine.

[3]  Stanislav N. Gorb,et al.  The design of the fly adhesive pad: distal tenent setae are adapted to the delivery of an adhesive secretion , 1998, Proceedings of the Royal Society of London. Series B: Biological Sciences.

[4]  Jim Hardie,et al.  THE ORGANS OF ADHESION IN THE APHID MEGOURA VICIAE , 1988 .

[5]  R. Full,et al.  Adhesive force of a single gecko foot-hair , 2000, Nature.

[6]  Nigel E. Stork,et al.  Experimental Analysis of Adhesion of Chrysolina Polita (Chrysomelidae: Coleoptera) on a Variety of Surfaces , 1980 .

[7]  B. Hölldobler,et al.  Attachment forces of ants measured with a centrifuge: better 'wax-runners' have a poorer attachment to a smooth surface. , 2000, The Journal of experimental biology.

[8]  Nigel E. Stork,et al.  A scanning electron microscope study of tarsal adhesive setae in the Coleoptera , 1980 .

[9]  Robert N. Fisher,et al.  A comparative analysis of clinging ability among pad‐bearing lizards , 1996 .

[10]  J. D. Gillett,et al.  The Climbing Organ of an Insect, Rhodnius prolixus (Hemiptera; Reduviidae) , 1932 .

[11]  R. Ruibal,et al.  The structure of the digital setae of lizards , 1965, Journal of morphology.

[12]  R. Ruibal,et al.  The structure and development of the digital lamellae of lizards , 1966, Journal of morphology.

[13]  S. Gorb,et al.  Ultrastructural architecture and mechanical properties of attachment pads in Tettigonia viridissima (Orthoptera Tettigoniidae) , 2000, Journal of Comparative Physiology A.

[14]  W. Dougherty Barnacle Adhesion: Reattachment of the Adult Barnacle Chthamalus Fragilis Darwin to Polystyrene Surfaces Followed by Centrifugational Shearing , 1990 .

[15]  S. Gorb Armored cuticular membranes in Brachycera (Insecta, Diptera) , 1997, Journal of morphology.

[16]  Y. Jiao,et al.  Adhesion measured on the attachment pads of Tettigonia viridissima (Orthoptera, insecta). , 2000, The Journal of experimental biology.

[17]  Shoziro Ishii,et al.  Adhesion of a Leaf Feeding Ladybird Epilachna vigintioctomaculta (Coleoptera : Coccinellidae) on a Virtically Smooth Surface , 1987 .

[18]  M. Renner,et al.  Pulvillus of Calliphora erythrocephala Meig. (Diptera : Calliphoridae) , 1977 .

[19]  E. Rabinowicz,et al.  Friction and Wear of Materials , 1966 .

[20]  Nigel E. Stork,et al.  The adherence of beetle tarsal setae to glass , 1983 .

[21]  K. Highley,et al.  Frictional properties of skin. , 1977, The Journal of investigative dermatology.

[22]  A. F. G. Dixon,et al.  The Mechanism by Which Aphids Adhere to Smooth Surfaces , 1990 .

[23]  G. Walker,et al.  The adhesive organ of the blowfly, Calliphora vomitoria: a functional approach (Diptera: Calliphoridae) , 1985 .

[24]  Stanislav N. Gorb,et al.  Frictional surfaces of the elytra-to-body arresting mechanism in tenebrionid beetles (Coleoptera : Tenebrionidae) : design of co-opted fields of microtrichia and cuticle ultrastructure , 1998 .

[25]  F. Podczeck,et al.  Development of an ultracentrifuge technique to determine the adhesion and friction properties between particles and surfaces. , 1995, Journal of pharmaceutical sciences.